Interactions of erythrocytes with an artificial wall: influence of the electrical surface charge

Electrical charge on any biological surface plays a crucial role in its interaction with other molecules or surfaces. Here, we study, under flow conditions, the interactions of erythrocytes with an artificial surface: a platinum microelectrode whose charge density ranges from –15 to +27 μC/cm². This artificial surface could be similar in surface charge to an endothelium or a biomaterial. In this model, interactions are measured as a transient relative increase of the electrolyte resistance obtained by impedance measurement of a microelectrode. A maximal interaction of erythrocytes with the charged surface is calculated in the 0 to +10 μC/cm² charge density range. At negative surface charge, a less efficient contact was obtained because of electrostatic repulsion forces. High positive surface charge (charge density >10 μC/cm²) does not improve the contact but induces a progressive decrease in the contact efficiency, which could be explained by a rearrangement of macromolecules on the erythrocyte surface or an effect of positive groups on the cell membrane. This work suggests that a greater surface area of contact is obtained in the 0 to +10 μC/cm² charge density range and that this is provided by more molecular bridges. Received: 23 February 1996 / Accepted: 26 April 1996     

Increased susceptibility of stored erythrocytes to anti-band 3 IgG autoantibody binding

When human blood was stored in a citrate-phosphate-dextrose (CPD) solution at 4°C, the susceptibility of the erythrocytes to binding of autologous IgG increased. The autologous IgG binding was partially inhibited by purified Band 3 glycoprotein and its oligosaccharides. The susceptibility of the erythrocytes to binding of ¹²⁵I-labeled anti-band 3 IgG autoantibody similarly increased. The results indicate that the anti-band 3 binding sites composed of Band 3 oligosaccharides were generated on the cell surface. The rate of the increase in the susceptibility of the stored cells to the antibody binding was lowered when blood was stored in a CPD solution containing L-ascorbic acid or erythorbic acid, suggesting involvement of an oxidative mechanism in the generation of the binding sites. The cytoplasmic glutathione level of erythrocytes gradually decreased during the blood storage. Storing blood in a CPD solution containing glutathione monoethylester or glutathione monoisopropylester resulted in partial prevention of the decrease in cytoplasmic glutathione level and of the increase in the IgG-binding ability of the cells. Similar preventive effect of glutathione monoethylester was observed in the binding of ¹²⁵I-labeled anti-band 3 autoantibody to the stored erythrocytes. Thus, the increase in the susceptibility of the stored erythrocytes to anti-band 3 binding may be caused, at least partially, by an oxidative stress resulting in a decreased cytoplasmic glutathione level.     

Determination with a microelectrode of membrane potential of giant human erythrocytes obtained by La(3+)-induced fusion

The effect of La3+ on the fusion of erythrocytes of blood stored for a week at +4 degrees C was studied. It was shown that the fusion of erythrocytes begins after one day of storage of blood. The most intensive fusion of erythrocytes was observed on day 4 of blood storage. As a result, giant cells with a size of 100 microns and more arise. The electrical potential of giant cells was measured using a microelectrode and was -6.6 +/- 1.5 mV.     

Cell age-related monovalent cations content and density changes in stored human erythrocytes

Conversion of erythrocyte membrane protein 4.1b to 4.1a occurs through a non-enzymatic deamidation reaction in most mammalian erythrocytes, with an in vivo half-life of approximately 41 days, making the 4.1a/4.1b ratio a useful index of red cell age [Inaba and Maede, Biochim. Biophys. Acta 944 (1988) 256-264]. Normal human erythrocytes distribute into subpopulations of increasing cell density and cell age when centrifuged in polyarabinogalactan density gradients. We have observed that, when erythrocytes were stored at 4 degrees C under standard blood bank conditions, the deamidation was virtually undetectable, as cells maintained the 4.1a/4.1b ratio they displayed at the onset of storage. By measuring the 4.1a/4.1b values in subpopulations of cells of different density at various time points during storage, a modification of the normal 'cell age/cell density' relationship was observed, as erythrocytes were affected by changes in cell volume in an age-dependent manner. This may stem from a different impact of storage on the imbalance of monovalent cations, Na(+) and K(+), in young and old erythrocytes, related to their different complement of cation transporters.     

Detection of Differences in Surface-charge-associated Properties of Cells by Partition in Two-polymer Aqueous Phase Systems

WHEN aqueous solutions of two polymers are mixed in certain proportions they may form two-phase systems^1,2 which can be buffered and used to partition and separate cells, particles and macromolecules by countercurrent distribution (CCD). Partition generally depends on polymer composition and concentration, the ionic composition and the charge sign of the material being partitioned. Such systems have been used to separate erythrocytes from white cells and erythrocytes on the basis of age. Changes in the surface properties of cells resulting from enzyme treatment or storage have also been demonstrated by this means³. Higher cell partition often accompanies increasing electrophoretic mobility which suggests that surface charge may be an important factor in partitioning^4–6. An apparent exception to this is the increased partition of stored human erythrocytes as compared with fresh⁷, as opposed to the mean electrophoretic mobility of both cell populations which remain identical⁸.     

Hemolysis and ATP Release from Human and Rat Erythrocytes under Conditions of Hypoxia: A Comparative Study

Red blood cells are involved not only in transportation of oxygen and carbon dioxide but also in autoregulation of vascular tone by ATP release in hypoxic conditions. Molecular mechanisms of the ATP release from red blood cells in response to a decrease in partial oxygen pressure still remain to be elucidated. In this work we have studied effects of hypoxia on red blood cell hemolysis in humans and rats and compared the effects of inhibitors of ecto-ATPase and pannexin on the release of ATP and hemoglobin from rat erythrocytes. The 20-min hypoxia at 37°C increased hemolysis of red blood cells in humans and rats 1.5- and 2.5-fold, respectively. In rat erythrocytes a significant increase in hypoxia-induced extracellular ATP level was found only in the presence of ecto-ATPase inhibitor ARL 67156. In these conditions we observed a positive correlation (R² = 0.5003) between the increase in free hemoglobin concentration and the ATP release. Neither carbenoxolon nor probenecid, the inhibitors of low-selectivity pannexin channels, altered the hypoxia-induced ATP release from rat erythrocytes. The obtained results indicate a key role of hemolysis in the ATP release from red blood cells.     

Promotion of Autolysis in Lactobacilli

The conditions of promotion of autolysis of three strains of Lactobacilli were investigated. The autolysis of L. acidophilus, L. helveticus and L. casei at exponential phase was remarkably enhanced by freezing storage at ?20°C overnight.

The turbidity decrease of L. acidophilus’ cell suspension corresponds to the increase of cell free nitrogen compounds, glucosamine and DNA component. All these compounds were more rapidly released from the cells stored at ?20°C than those stored at 3°C. The cells which were harvested at the exponential phase had higher autolytic activity than those at stationary phase. The storage of the cells at ?20°C for 2 days or more could effectively promote the autolysis.

The activity was increased by Ca²⁺ or Mg²⁺. Optimum pH of the autolytic enzyme of L. acidophilus was 6~7.     

Liquid preservation of highly purified human granulocytes

Highly purified human granulocytes isolated from continuous flow centrifugation leukapheresis concentrates by counterflow centrifugation-elutriation were stored at 4 °C in concentrations of 6 × 10⁶ to 1 × 10⁷ granulocytes per milliliter for up to 14 days. The in vitro physiological function assays of phagocytosis, oxygen consumption associated with phagocytosis, bacterial growth inhibition, chemotaxis, and five enzyme analyses indicated good storage survival for up to 4 days. Stored granulocytes separated from other blood cells have greater storage stability than granulocytes stored as leukapheresis concentrates. After 14 days of storage a small percentage of granulocytes still maintained all physiological functions, with the exception of chemotaxis. Of the five enzymes assayed, only the enzyme activity of leucine aminopeptidase decreased significantly by the 14th day of storage. The storage stability of each physiological function assayed decreased as follows: bacterial growth inhibition (most stable), phagocytosis, oxygen consumption, and chemotaxis (least stable).     

Effect of extracellular Ca2+, K+ and OH− on erythrocyte membrane potential as monitored by the fluorescent probe 3,3′-dipropylthiodicarbocyanine

Changes in fluorescence intensity of thiodicarbocyanine, DiS-C₃(5), were correlated with direct microelectrode potential measurements in red blood cells from Amphiuma means and applied qualitatively to evaluate the effects of extracellular Ca²⁺, K⁺ and pH on the membrane potential of human red cells. Increasing extracellular [Ca²⁺] from 1.8 to 15 mM causes a K⁺-dependent hyperpolarization and decrease in fluorescence intensity in Amphiuma red cells. Both the hyperpolarization and fluorescence change disappear when the temperature is raised from 17 to 37°C. No change in fluorescence intensity is observed in human red cells with comparable increase in extracellular Ca²⁺ in the temperature range 5–37°C. Increasing the extracellular pH, however, causes human red cells to respond to an increase in extracellular Ca²⁺ with a significant but temporary loss in fluorescence intensity. This effect is blocked by EGTA, quinine or by increasing extracellular [K⁺], indicating that at elevated extracellular pH, human erythrocytes respond to an increase in extracellular Ca²⁺ with an opening of K⁺ channels and associated hyperpolarization of the plasma membrane.     

Preservation of resuspended red cell concentrate. Analysis of purines, nucleosides and nucleotides in stored red cells

Purine nucleotides of red blood cells (RBC) during storage in two different media with addition of adenine/nicotinamide (NAP) or adenine/guanosine (CDS-AG) were estimated by HPLC. Synthesis of guanine nucleotides reached a maximum after 14 days in RBC stored with adenine/guanosine. The higher adenine concentration in the NAP solution (3 mmol/l) did not increase adenine consumption and the ATP-level of the erythrocytes. The adenylate energy charge (AEC) of RBC decreased from 0.91 to 0.63 during 42 days of storage in CDS-AG solution.     

The ratio of amount of haemoglobin to total surface area of erythrocytes in mammals

The literature provides all the data needed to calculate the ratio between the amount of haemoglobin and the total surface area of erythrocytes in 54 species of mammals ranging in body mass from 2.5 g to more than 1000 kg. Analysis shows that the concentration of haemoglobin (Hb; g%) does not depend on the body mass of the mammals studied. The number of erythrocytes in 1 mm³ of blood (RBC; 10⁶×mm⁻³) is significantly lower, and the diameter of these cells significantly higher, among larger mammals as opposed to smaller ones. The result is that the total surface area of erythrocytes in 1 mm³ of blood (TSAE; mm²×mm⁻³) is significantly lower among larger mammals, while the Hb/TSAE ratio (pg×μm⁻²) is significantly greater. These results point to the smaller size of erythrocytes of smaller mammals permitting much greater numbers to exist, thereby producing a greater TSAE and smaller Hb/TSAE ratio. The greater total surface area of red blood cells per unit volume of blood in small mammals can in turn be presumed to allow for full saturation of haemoglobin by oxygen, even where the period of contact between erythrocytes and air in the lungs is shorter than in their larger counterparts.

     

Magneto-electro-fusion of human erythrocytes

In inhomogeneous (static) magnetic fields close contact between ‘magnetic’ human erythrocytes was established. The cells were made magnetic by incubating them in a medium containing small Fe₃O₄-particles which adsorbed to the outer membrane surface. Fusion was induced by applying two electric field pulses (field strength: 8.5 kV · cm^?1; duration: 60 μs) to the magnetically collected cells. This procedure allowed the use of electrically conductive media (3 · 10^?1 Ω^?1 · cm^?1). Fusion of red blood cells occured very often. If cell suspensions of high density were used fusion resulted in the formation of giant red blood cells with osmotically intact membranes.     

Capillary electrophoresis of erythrocytes

Capillary electrophoresis (CE) of erythrocytes from different sources under various conditions is reported in this paper. It was found that erythrocyte samples from sheep, duck, and human showed characteristic and reproducible elution peaks, and that the retention times of A-, B-, AB-, and O-type erythrocytes from human blood were distinctively different; even subtle differences, among individuals with the same blood type could be detected by CE. A strictly linear correlation was obtained between the peak area and the amount of human erythrocyte over a range of 4.8 x 10(2)-1.9 x 10(4) cells (r=0.999), indicating that CE could be used for rapid and accurate quantification of erythrocytes. Using this CE protocol, the decrease of the surface electrical charge of erythrocyte during storage was confirmed. Therefore, this work demonstrated that CE could be a useful alternative for characterizing and quantifying erythrocytes or other cells.     

Lipid peroxidation and antioxidant defense of erythrocytes during bubbling air ionization of donor packed red blood cells

It is shown that erythrocytes in packed red blood cell preparations can be maintained in native state for a long time using bubbling air ionization (BAI). The BAI procedure proposed to prolong the storage period of donor erythrocytes makes it possible to reduce the level of destructive processes in packed cells stored until use, as indicated by a decrease in the lipid peroxidation intensity and an increase in the antioxidant activity in them.     

Regulatory properties of rabbit red blood cell hexokinase at conditions close to physiological

The true level of hexokinase in rabbit erythrocytes was determined by three different methods, including the spectrophotometric glucose-6-phosphate dehydrogenase coupled assay and a new radioisotopic assay. The value found at 37°C (pH 7.2) was 10.23±1.90 μmol/h per ml red blood cells, which is lower than previously reported values. More than 40 cellular components of the rabbit erythrocytes were tested for their effects on the enzyme. Their intracellular concentrations were also determined. Several of these compounds were found to be competitive inhibitors of the enzyme with respect to Mg·ATP^2?. Furthermore, reduced glutathione at a concentration of 1 mM was able to maintain hexokinase in the reduced state with full catalytic activity. The ability of orthophosphate to remove the inhibition of some phosphorylated compounds was examined under conditions similar to cellular (pH 7.2 and 50 μM of orthophosphate) and found to be of no practical interest. In contrast, the binding of ATP^4? and 2,3-diphosphoglycerate to the rabbit hemoglobin significantly modifies their intracellular concentrations and the formation of the respective Mg complexes. The pH-dependence of the reaction velocity and of the kinetic properties of the enzyme in different buffer systems were also considered. This information was computerized, and the rate of glucose phosphorylation in the presence of the mentioned compounds was determined. The value obtained, 1.94±0.02 μmol/h per ml red blood cells, is practically identical to the measured rate of glucose utilization by intact rabbit erythrocytes (1.92±0.3 μmol/h per ml red blood cells). These results provide further evidence for the central role of hexokinase in the regulation of red blood cell glycolysis.     

Stabilization of the adenylate energy charge in erythrocytes of rats and humans at high altitude hypoxia.

1. Stabilization of adenylate energy charge and control of adenylate pool were analysed in the erythrocytes of the rat and the human exposed to highly hypoxic conditions. 2. Red cell energy charge was decreased in the rats exposed to a simulated altitude of 5000-8000 m, and then recovered to the normal value with the depletion of adenylate pool. 3. The energy charge and the adenylate pool size of the human erythrocytes did not show any change under highly hypoxic conditions. 4. Anaerobic incubation of rat erythrocytes caused a marked decrease in the energy charge, and its recovery was accompanied by the depletion of total adenylates. 5. The energy charge and total adenylates of human red cells did not change under the anaerobic incubation of erythrocytes. 6. These results suggest that the energy charge of rat erythrocytes can be controlled by depletion of the adenylate pool, but the adenylate degradation is not responsible for the stabilization of the energy charge in human erythrocytes.     

Lysis of erythrocytes from stored human blood by phospholipase C (Bacillus cereus).

The ability of phospholipase C (Bacillus cereus) to lyse erythrocytes from human blood that had been stored under Transfusion Service conditions for up to 16 weeks has been examined. When incubated at 20 degrees C with enzyme (0.03 mg/ml, 55 units/ml) for up to 1 h fresh erythrocytes were not lysed. After about 4 weeks of storage a population of very readily lysed erythrocytes appeared. The morphological changes in erythrocytes from blood stored up to 16 weeks were examined by scanning electron microscopy. The proportion of very readily lysed erythrocytes correlated well with the proportion of spheroechinocytes I. This morphological form was shown to be preferentially removed by phospholipase C and before lysis a transient appearance of smooth spheres occurred. The decrease in blood ATP concentrations on storage was measured and found to correlate with the disappearance of discoid erythrocyte forms, but not directly with the increased susceptibility of the erythrocytes to lysis by the enzyme. However, erythrocytes of up to at least 15 weeks of age could be made less susceptible to lysis by pre-incubation in a medium designed to cause intracellular regeneration of ATP. During the lysis of spheroechinocytes I by electrophoretically pure recrystallized phospholipase C a rapid degradation of phosphatidylcholine, phosphatidylethanolamine and phosphatidylserine + phosphatidylinositol) occurred together with a slower degradation of sphingomyelin.     

The effect of inosine, inorganic phosphates and pyruvate on erythrocyte glycolysis metabolites under conditions of preservation]

Human erythrocytes were stored as resuspensions in solutions containing citrate (Z), inosine + citrate (I), inosine + phosphate (IP), and inosine + phosphate + pyruvate (IPP). The storage was made at + 4 degrees C for 6 weeks; the initial pH-value amounted to 7.4 at + 4 degrees C. The cellular concentrations of 2.3 DPG, ATP, G6P, FDP and DOAP + GAP were determined. The following results were obtained: 1. During the storage in stored Z-blood the 2.3 DPG concentration will fall below 10% of its initial value; it will remain nearly unchanged in stored I-blood and will increase to 170% in stored IP-blood, to 270% of its initial value in stored IPP-blood. 2. The ATP concentration of cells will fall to about 50% of its initial value at the beginning of the storage of all stored blood. After that it will only increase to about 80% of its initial value in stored IP- and IPP-blood. 3. During the storage the G6P concentration will increase to the highest degree in stored IPP-blood and if high pyruvate concentrations are not present, it will have a reciprocal behaviour towards the FDP and triosephosphate level. The results were discussed in view of the regulation of glycolysis under storage conditions.     

Storage of marine fish erythrocytes in liquid nitrogen

The preservation of erythrocytes from cod ( Gadus morhua ), saithe ( Pollachius virens ) and mackerel ( Scomber scombrus ) at −196° C was studied using dimethyl sulphoxide (DMSO) as a cryoprotectant. Erythrocyte recoveries of greater than 90% were obtained from all species and cod erythrocytes were stored for eighteen months with insignificant lysis. Larger quantities of blood were stored by removal of plasma from citrated blood prior to the addition of DMSO solution, and by storage of pelleted frozen blood in aluminium canisters in liquid nitrogen. Maximum recoveries of washed intact erythrocytes required thawing of pellets in 125% DMSO solution and washing with buffer containing decreasing concentrations of DMSO. Washed erythrocytes kept at 4° for at least two days showed little haemolysis, were morphologically similar to fresh erythrocytes and equally susceptible to the δ-haemolysin of Staphylococcus aureus .     

Comparison of the Surface Proteins and Glycoproteins On Erythrocytes of Calves Before and During Infection With Babesia Bovis

The surface proteins and glycoproteins on red cells from normal and Babesia bovis-infected calf blood have been compared. Several radiolabeling probes were used to label specifically external membrane molecules which were then separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and identified by autoradiography or fluorography. No differences were observed among the Coomassie Blue-stained membrane proteins of erythrocytes from individual uninfected calves. Comparison of red cells from these animals also indicated no qualitative differences in the surface proteins with accessible tyrosyl residues labeled by lactoperoxidase-catalyzed radioiodnation, although some quantitative variation in the uptake of radioactivity into particular proteins was observed. the major radioiodinated bands on normal bovine erythrocytes had Mr of 165, 130, 90, and 45 kiloDaltons. However, labeling of surface glycoproteins by the periodate/[³H]NaBH₄ and galactose oxidase (± neuraminidase)/[³H]NaBH₄ methods showed significant differences in the surface proteins of red cells from individual uninfected calves. of 14 animals tested, 5 had major labeled glycoproteins of unique Mr. No changes were observed in radioiodinated surface proteins of total red cell samples from infected calves with 0.5-6% parasitemia. Radioiodination of concentrated infected red cells from the same samples (concentrated by selective hypotonic lysis of uninfected erythrocytes in KC1) resulted in the labeling of 3 new surface proteins, with Mr of 118, 115, and 60 kiloDaltons. the same new ¹²⁵I-labeled bands were identified on infected cells from 3 avirulent strains of B. bovis used in vaccine production. Furthermore, in concentrated infected cells there was very poor radiolabeling of major bands strongly labeled on uninfected cells (Mr 165, 130, and 90 kiloDaltons), suggesting parasite-induced loss of these proteins. Although there were some differences in ³H-labeled surface glycoproteins of red cells from normal and. B. bovis -infected blood, they were restricted to minor labeled bands and were not seen consistently. the labeled surface glycoproteins of concentrated infected cells were very similar to those of the uninfected red blood cells from infected blood.